Mechanism of adenosine production by isolated rat heart mitochondria

Adenosine production by isolated rat heart mitochondria was examined and was observed to be dependent on an active adenine nucleotide transporter and a functional 5'-nucleotidase. It was found that mitochondria do not transport adenosine. These results suggest that mitochondria provide AMP for an extramitochondrial 5'-nucleotidase and this was verified by direct measurement of extramitochondrial levels of AMP and adenosine. A possible role for mitochondria in myocardial adenosine production is discussed.     

Oxidation of erucic acid and erucyl-CoA by isolated rat heart mitochondria: comparison to oleic acid]

The oxidation of [14 14-C] or [1 14-C] erucic acid by isolated mitochondria from Rat heart has been studied and compared with that of [10 14-C] oleic acid in varying conditions of incubation. Erucic acid is converted to CO2 and acid-soluble compounds much more slowly than oleic acid. The acid-soluble compounds which have been identified are acylcarnitines, ketone bodies and intermediates from the Krebs cycle; they are found in similar proportions for both substrates. Moreover, the oxidation rate of erucyl-CoA is comparable, if not equal, to that of oleyl-CoA in the same conditions. These results are discussed here. They lead to the conclusion that erucic acid is oxidized by isolated Rat heart mitochondria through the beta oxidation pathway, and that its oxidation is limited owing to its slow activation rate.     

A transport system for coenzyme A in isolated rat heart mitochondria

The ability of isolated rat heart mitochondria to take up coenzyme A (CoA) from the incubation medium was studied. Mitochondria accumulated CoA in a time- and concentration-dependent manner. The accumulation process occurred in two phases. Within the first 30 s of incubation, mitochondrial content of CoA increased, and this phase did not plateau in the concentration range studied. Following this initial increase, a second slower phase of CoA accumulation occurred which plateaued around 50 microM CoA. The initial phase was decreased significantly by ATP or by carboxyatractyloside. In contrast, the presence of ATP or carboxyatractyloside did not affect the second phase. Decreasing the temperature from 30 to 0 degrees C did not affect the initial phase, but the second phase was almost abolished. In the presence of metabolic inhibitors (either 2,4-dinitrophenol or a combination of rotenone and antimycin), the initial "binding" phase was not affected; but the second "uptake" phase was abolished. These results suggest that the first phase of mitochondrial CoA accumulation is probably CoA binding to adenine recognizing sites on the mitochondria while the second phase may represent a specific uptake process for CoA which, although not directly ATP-dependent, is energy-dependent.     

Effects produced on isolated rat heart mitochondria by beryllium sulfate.

Beryllium sulfate increases the rate of oxygen uptake by isolated rat heart mitochondria. This effect is proportional to the Be²⁺ concentration. Beryllium binds to a limited number of sites on the isolated mitochondria and stimulates the mitochondrial ATPase. These effects, which appear to be related to an uncoupling of respiration, cause swelling of the mitochondria.     

The disposition of citric acid cycle intermediates by isolated rat heart mitochondria

The mechanism of depletion of tricarboxylic acid cycle intermediates by isolated rat heart mitochondria was studied using hydroxymalonate (an inhibitor of malic enzymes) and mercaptopicolinate (an inhibitor of phosphoenolpyruvate carboxykinase) as tools. Hydroxymalonate inhibited the respiration rate of isolated mitochondria in state 3 by 40% when 2 mM malate was the only external substrate, but no inhibition was found with 2 mM malate plus 0.5 mM pyruvate as substrates. In the prescence od bicarbonate, arsenite and ATP, propionate was converted to pyruvate and malate at the rates of 14.0 ± 2.9 and 2.8 ± 1.8 nmol/mg protein in 5 min, respectively. Under these conditions, 0.1 mM mercaptopicolinate did not affect this conversion, but 2 mM hydroxymalonate inhibited pyruvate formation completely and resulted in an accumulation of malate up to 13.2 ± 2.9 nmol/mg protein. No accumulation of phosphoenolpyruvate was found under any condition tested. It is concluded that malic enzymes but not phosphoenolpyruvate carboxykinase, are involved in conversion of propionate to pyruvate in isolated rat heart mitochondria.     

Uncoupled oxidation in rat heart mitochondria

Isolated heart mitochondria possessing a high phosphorylation efficiency with pyruvate and malate as substrates oxidize NADH and ascorbate unassociated with ADP phosphorylation. This uncoupled pathway is expressed partially when succinate or NAD-linked substrates are oxidized. The uncoupled oxidation is likely to be the result of the presence of a mitochondrial population with the high-permeable inner membrane in intact tissues. The nature and origin of a uncoupled respiratory system and its role in the thermoproduction of endotherms are discussed.     

Origin of guanine nucleotides in isolated heart mitochondria

Presence of guanine nucleotide within the matrix of mitochondria is uncontested; the mechanism by which GTP takes up residence in the matrix is unknown. In this report, we demonstrate for the first time that direct transport of guanine nucleotide across the inner membrane of heart mitochondria is possible. Transport of guanine nucleotides from the medium to the matrix was suggested by inhibition of translation in isolated rat heart mitochondria when GTP-gamma-S was added to the medium. This result suggested that GTP was one source of matrix GTP. Other sources were investigated by measuring matrix uptake and conversion to GTP of several purines, purine nucleosides, and purine nucleotides. Results demonstrated that [14C]-guanine and [3H]-guanosine were not taken up by isolated mitochondria and were not converted to any other compound. While [14C]-ATP and [3H]-AMP were taken up readily into the matrix, radioactivity was never associated with a guanine compound. [3H]-IMP was not taken up into the matrix and was never converted to another compound. Our data showed that label added as [3H]-GTP, [3H]-GDP, or [3H]-GMP was readily taken up and concentrated in the matrix of isolated mitochondria.     

Fumarate permeation in rat heart mitochondria

The possible fumarate translocation in rat heart mitochondria is examined. This substrate, which is claimed to be a non permeant ion in rat liver mitochondria appears to cross the mitochondrial membrane in cardiac mitochondria. This conclusion was proposed on the basis of experimental results which show swelling by rat heart mitochondria in ammonium fumarate, uptake by mitochondria of fumarate, Pi efflux from the matrix induced by fumarate and appearance of malate in the reaction mixture which follows the addition of fumarate to the mitochondria and depends on the fumarase activity. The existence of a carrier unknown so far as well as a possible physiological role of this transport is proposed.     

Ammonia formation in isolated rat liver mitochondria

Studies of isolated rat liver mitochondria were undertaken in order to evaluate the importance of glutamate transport, oxidation reduction state, and product inhibition on the rates of formation of ammonia from glutamate. Uptake and efflux of glutamate across the mitochondrial membrane were measured isotopically in the presence of rotenone. Efflux was stimulated by H+ in the mitochondrial matrix and was found to be first order with respect to matrix glutamate except when the matrix pH was unphysiologically low. The data suggest that the Km of matrix glutamate for efflux is decreased by H+. Matrix H+ also appeared to stimulate glutamate uptake, but the effect was to increase both the Km of medium glutamates and Vmax. Mitochondria were incubated at 15 and 28 degrees C with glutamate and malonate. Under these conditions, glutamate was metabolized only by the deamination pathway. Flux was evaluated by assay of ammonia formation. Oxidation reduction state was varied with ADP and uncoupling agents. Matrix alpha-ketoglutarate was varied either by the omission of malonate from the incubation media or by adding alpha-ketoglutarate to the external media. Influx and efflux of glutamate could be calculated from previously determined transport parameters. The difference between calculated influx and efflux was found to be equal to ammonia formation under all conditions. It was, therefore, possible to evaluate the relative contributions of oxidation reduction state, transport, and product inhibition as effectors of ammonia formation. The contribution of transport was relatively small while oxidation reduction state exerted a large influence. alpha-Ketoglutarate was found to be a potent competitive inhibitor of ammonia production and glutamate dehydrogenase. Inhibition of glutamate dehydrogenase by alpha-ketoglutarate was judged to be a potentially important modulator of metabolic fluxes.     

Impact of lactate in the perfusate on function and metabolic parameters of isolated working rat heart

The goal of this study was to investigate the effect of 1 mM exogenous lactate on cardiac function, and some metabolic parameters, such as glycolysis, glucose oxidation, lactate oxidation, and fatty acid oxidation, in isolated working rat hearts. Hearts from male Sprague-Dawley rats were isolated and perfused with 5 mM glucose, 1.2 mM palmitate, and 100 μU/ml insulin with or without 1 mM lactate. The rates of glycolysis, glucose, lactate, and fatty acid oxidation were determined by supplementing the buffer with radiolabeled substrates. Cardiac function was similar between lactate+ and lactate− hearts. Glycolysis was not affected by 1 mM lactate. The addition of lactate did not alter glucose oxidation rates. Interestingly, palmitate oxidation rates almost doubled when 1 mM lactate was present in the perfusate. This study suggests that subst rate supply to the heart is crucially important when evaluating the data from metabolic studies.